From what I have understood it is a quantum compuational approach and you need lots of informaton computationally to describe exact the picture of what is going on GR in terms of comological events

One thing that comes to mind is LIGO analysis of the information coming from the detectors. This is a quite a store house of information that has to correspond. Many detectors(space based and earth based) measuring for the same event detection.

Just yesterday Lawrence Berkeley National Laboratory, and several key partners put together a demonstration system running a real-world scientific application to produce data on one cluster, and then send the resulting data across a 10 Gigabit Ethernet connection to another cluster, where it is then rendered for visualization. Publicly proving more than switch interoperability, the demonstration was a first.

This has been part of the question for quantum computational factors that have been very interesting for me in what is being done at PI and other places.

So this leads us to the question of how such a approach computationally help in this direction.

Introduction to Cryptology

Whether such a "quantum computer" can realistically be built with a value of L that is large enough to be of practical use is a topic of much debate. However, the mere possibility has led to an explosive renaissance of interest in the host of curious and classically counterintuitive properties associated with entangled states. Other phenomena that rely on nonlocal entanglement, such as quantum teleportation and various forms of quantum cryptography, have also been demonstrated in the laboratory

How would you computationally discribe the tree structure reductionism has supplied for us to consider?

LQG comparison in Glast considerations triggered some response in my own mind, but I found limitations.

Given the dearth of knowledge about gravity in the subcentimeter range, the group is looking for any kind of deviation from expectations, not just extradimensional effects, he says. Nonetheless, the excitement about extra dimensions helps spur the group on, Price says.

If the strength of gravity takes a sharp turn upward at around 1 TeV, as the Stanford-Trieste scenario implies, an opportunity opens for testing this theory also in accelerators. Collisions at such energies could produce gravitons in large numbers, and some of these particles would immediately vanish into the extra dimensions, carrying energy with them. Experimenters would look for an unusual pattern of so-called missing energy events.

This and more subtle effects of extra dimensions could show up at existing accelerators, such as LEP and the Tevatron at Fermilab, only if the dimensions have scales nearly as big as a millimeter. The powerful LHC will greatly improve the chances for detecting missing energy events and other prominent extradimension effects.

Consider the thread Marcus started here, and you will undertand the quantum issues that need a process for discerning this nature. The LQG perspective is very telling to me. They are carrying a torch in a specific area.

Strings from this perspective has to account for that missing energy Cosmologically this makes it much easier? Blackhole cosmologically or blackhole in collider. It's really the same issue for strings?